Arrangement for the one-dimensional or multi-dimensional determination of the position of a load suspension point in hoists

ABSTRACT

The stopping of a load suspended from a crane requires a swing control or, respectively, a swing damping. Upon employment of microwave measuring units, spacings between a carrying cable suspension and a load suspension point are determined on the basis of transit time measurements. The position of the load suspension point can be determined from the transit time measurements quickly and with high precision. Swinging motions are avoided by controlled opposing control of the carrying cable suspension.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention is directed to the determination of the position of loadssuspended from a carrying cable in hoists that are one-dimensionally ormulti-dimensionally moved by corresponding actuating drives.

The stopping of a crane or of the load suspended from the crane over aset-down point normally causes an overshooting or swinging of the load.The time delay for the set-down event resulting therefrom leads to aconsiderable lengthening of the overall transport time of the load.Rocking or, respectively, swinging of the load, however, can be entirelyor partially stabilized by movements of the crab or, respectively, ofthe crane or of the actuating drives executed correspondinglyanti-phase. The constant position measurement of the load suspensionmeans is necessary therefor, whereby a defined point, the loadsuspension point, is expediently considered. In the general case, thelateral position in the x-direction and y-direction of the coordinatesystem must be identified with a precision of below ±1 cm proceedingfrom the crab plane. The measuring time connected therewith should notexceed a few milliseconds. Such measurements are usually implemented innon-contact fashion and leads to a position determination in space.These measurements, however, are disrupted by certain environmentalconditions such as temperature, rain, snow, darkness or bright sunlightand the like.

Currently known methods for an average position action of the above typeare implemented either by an opto-electronic acquisition of the loadsuspension point or via a swing angle measurement with mechanical ormagnetic measuring means in the proximity of the cable suspension duringoperation of the crab. Given the latter method, however, cableundulations can considerably falsify the measured result. In thefirst-cited, opto-electronic method, the acquisition of the loadsuspension point is negatively influenced by the environmentalconditions. Thus, the dependability of these methods is not alwaysassured. Over and above this a two-dimensional position determinationwithin a few milliseconds presents difficulties. Although opticalreflectors or infrared light sources have been applied in the meantimefor better recognition of the load suspension means for theopto-electronic method, these devices cannot eliminate the disadvantagesof said method.

SUMMARY OF THE INVENTION

The invention is based on the object of making an arrangement availablefor the determination of the position of a load carried by cable of ahoist. The position determination should function constantly anddisruption-free and be the basis for a damping of swing.

In an embodiment, microwave range-finding is utilized and variousinstances of problem-solving are described on the basis of said object.

The invention is based on the perception that significant advantages canbe achieved with the utilization of microwave range-finding technologyfor a position determination of the load in hoists. The particularadvantage is thereby comprised in the propagation of the microwaves thatis undisturbed by the environmental conditions. Over and above this, ahigh precision can be achieved in the range-finding, and the measuringtimes are extremely short. Microwave range-finding is based onmeasurements of the transit time of the signals that are sent out and inturn received. The frequency range lies between 1 and 100 GHz. Amicrowave transmitter transmits a spherical wave that is received by acorresponding receiver. When a microwave signal is deflected via what isreferred to as a retro-reflector, then this in turn reflects a sphericalwave.

Proceeding from a lateral carrying cable suspension, i.e. a carryingcable suspension movable in x-direction and y-direction, a swing willalways occur upon arrest when moving a load suspended at the carryingcable. The inventive arrangement provides that microwave measuring unitsare attached with which the distance measurements between carrying cablesuspension and load suspension point can be implemented, whereby theapproximate measuring directions describe a finite angle with thecarrying cable. These microwave measuring units are arranged, on the onehand, with a known position relative to the carrying cable suspensionand, on the other hand, with a known position relative to the loadsuspension point. For a position measurement of the load suspensionpoint, it is important to optimally design the angle between thecarrying cable and the measuring directions corresponding to themicrowave measuring units. Dependent on the respective application, themicrowave measuring units are arranged at approximately equal intervalsaround the carrying cable.

According to the invention, the microwave measuring technology isadvantageously utilized at hoists, whereby the position determinationensues one-dimensionally, two-dimensionally or three-dimensionallydependent on the respective application or use. Correspondingly, theequipment of the inventive arrangement exhibits a different plurality ofmicrowave measuring units.

The position of the load suspension point can be three-dimensionallydetermined by employing at least three microwave measuring units. Inthis system, respectively three ranges are determined on the basis oftransit time measurements. The position of the load suspension point isthen calculated from the intersection of the three spherical surfaceswith the radii that correspond to the distance between transmitter andreceiver or, respectively, transmitter/receiver combination andretro-reflector, and the centers that are respectively represented bythe positions of the transmitters or, respectively, transmission andreception combinations. Since a damping of the swing of the loadsuspension point for essentially lateral movements comes intoconsideration for standard hoists, there is the possibility of obtainingthe acquisition of the z-direction, i.e. of the height coordinate, by ameasurement of the length of the carrying cable as a substitute for onemicrowave measuring unit. In this case, two microwave measuring unitswould be employed in addition to the measurement of the cable length.The height of the load suspension point, however, is more reliablydetermined by employing three microwave measuring units than it is bymeasuring the cable length.

When the load suspension point can only move one-dimensionally back andforth, the position measurement of the load suspension point initiallyrequires two microwave measuring units. To this end, it is necessarythat the connecting line between the two transmission or, respectively,transmission and reception units lies in the swinging direction of theload suspension point. The connecting line should at least be parallelto the swinging direction. A load suspension point two-dimensionallymovable in a vertically residing plane can be measured with thisembodiment.

A likewise two-dimensional position measurement for the load suspensionpoint derives when the position of the load suspension point isdetermined with a microwave measuring unit lying in the plane of motionof the load suspension point and the measurement of the cable length.Since the height value is of no direct significance again for practicalswing damping, the determination thereof can be accomplished bemeasuring the length of the carrying cable. Since the excursion of acarrying cable can be set at a maximum of 6°, the swing damping isimplemented quasi-linearly. Knowledge of the height value(z-coordinate), however, can be employed for the exact set-down of theload.

Other objects and advantages will be apparent to those skilled in theart upon review of the figures, the detailed description of thepreferred embodiments and the appended claims.

BRIEF DESCRIPTION OF THE FIGURES

Exemplary embodiments are described below with schematic Figures.

FIG. 1 illustrates an inventive microwave measurement arrangement forthe three-dimensional determination of the load suspension point;

FIG. 2 illustrates an inventive microwave measurement arrangement withtwo microwave measuring units, whereby a three-dimensional determinationof the load suspension point can be achieved by an additional cablelength measurement;

FIG. 3 illustrates an inventive microwave measurement arrangement fortwo-dimensional position determination of the load suspension point uponutilization of two microwave measuring units;

FIG. 4 illustrates an arrangement corresponding to FIG. 3, whereby onemicrowave measuring unit is replaced by the cable length measurement.

It should be understood that the drawings are not necessarily to scaleand that the embodiments are sometimes illustrated by graphic symbols,phantom lines, diagrammatic representations and fragmentary views. Incertain instances, details which are not necessary for an understandingof the present invention or which render other details difficult toperceive may have been omitted. It should be understood, of course, thatthe invention is not necessarily limited to the particular embodimentsillustrated herein.

DETAILED DESCRIPTION OF THE PRESENTLY PREFERRED EMBODIMENTS

FIG. 1 illustrates a carrying cable suspension 7 with a carrying cable 3and a load attack point 1. The carrying cable suspension 7 istwo-dimensionally movable in planar x/y-directions. A height movabilityof the load 2 is established by winding up and unwinding the carryingcable is the carrying cable suspension 7. The transmitter/receivercombinations 4, 5, 6 laterally spaced from the carrying cable suspension7 respectively beam a microwave signal that is fashioned as a sphericalwave in the direction toward the retro-reflector or retro-reflectors 8.This microwave signal is respectively reflected at a reflectivecomponent hereinafter referred to as the retro-reflector 8 and receivedat the respective transmitter/receiver combination 4, 5, 6. This formsthe basis for the transit time measurement and distance determinationfor the distances 41, 51, 61. As a result of their position permicrowave measuring unit, the combinations 4, 5, 6 and the correspondingretro-reflectors respectively determine the direction in which thedistance should be measured. The position of the load suspension pointis determined with the described evaluation via intersecting sphericalsurfaces whose center is respectively represented by the combinations 4,5, 6, and, following thereupon, an antiphase movement for the carryingcable suspension 7 is targeted, so that a swing damping of the swingingload suspension point 1 ensues. The measurement can ensue in themillisecond range with a precision of ±1 cm, as a result whereof aconstant position determination is possible.

Correspondingly, the swing damping can be iteratively or successivelycontinued up to the standstill of the load suspension point 1 or,respectively, of the load 2, or a control implemented in time prevents aswinging from the very outset. When, according to FIG. 1, threemicrowave measuring units 4-8, 5-8, 6-8 are employed, then the heightcoordinate z can be determined in addition to the two-dimensional swingdamping. Otherwise, this is relatively imprecisely determined viameasurement of the cable length. A uniform fashioning of theretro-reflectors 8 can, for example, cover all three microwave measuringunits at the same time. Different frequencies can be utilized fordifferentiating between the different measuring units.

In FIG. 2, the carrying cable suspension 7 is likewise two-dimensionallymovable in planar directions. The load suspension point 1 can bethree-dimensionally determined. Analogous to FIG. 1, thetransmitter/receiver combinations 4, 5 are fashioned to measuring unitswith the retro-reflector 8, whereby they do not lie on a straight linethat proceeds through the carrying cable suspension 7 at the same time.The length of the carrying cable 3 is mechanically measured. With anarrangement according to FIG. 2, thus, a three-dimensional positiondetermination and at least a two-dimensional swing damping acting inplanar directions are likewise possible and a height determination ofthe load suspension point 1 can be achieved.

By contrast to FIGS. 1 and 2, FIGS. 3 and 4 exhibit significantlimitations with respect to the degrees of freedom. The carrying cablesuspension 7 can only be moved one-dimensionally along the y-axis.Correspondingly, the load suspension point 1 with the load 2 can swingonly in a perpendicularly residing plane. This swinging can be damped bycorresponding anti-phase drive control in the carrying cable suspension7, whereby the constant determination of the position of the loadsuspension point 1 again occurs partly or completely with the microwavemeasurement technology.

Two microwave measuring units are used in FIG. 3, the units 4-8 and 5-8.The transmitter/receiver combinations 4, 5 according to FIG. 3 lie atopposite sides of the carrying cable 3 and in the swing plane in theplane of motion of the load suspension point 1 or, in other words, on astraight line through the carrying cable suspension 7. A one-dimensionalswing of the load suspension point 3 can be identified and compensatedwith the arrangement according to FIG. 3. In an even more simplifiedcase, one microwave measuring unit can be replaced via the measurementof the cable length, so that only a single microwave measuring unit ispresent according to FIG. 4. In FIG. 4, the transmitter/receivercombination 6 must likewise lie in the swinging plane of the loadsuspension point 1.

The different embodiments of the invention shown in FIGS. 1 through 4optionally yield a high measuring precision when measurement isundertaken entirely via microwave measuring units. When the cable lengthmeasurement at the carrying cable 3 is used, this being equivalent to amechanical measurement, sacrifices with respect to the precision are tobe anticipated. A typical frequency for a microwave measuring unit is,for example, 24 GHz and a clock time for the measurements lies at, forexample, 10 ms.

A reference mark outside of the crane region can be exploited, forexample, upon simultaneous or partially alternative employment ofcentral locating systems. An optimum matching can thus be undertakentaking the time and the technical-qualitative possibilities, i.e. themeasuring precisions, of different locating systems into consideration.

When, for example, a hall-bound locating system is employed, then it isconceivable to centrally determine the position of the carrying cablesuspension (7), separately from the likewise central determination ofthe position of the load suspension point (1). The central locatingsystem can thereby be adapted in an arbitrary form to the internallocating system of the crane. In addition to the measuring precision,the time availability together with the speed of the signal evaluationis an essential criterion for a job division between the internallocating or, respectively, positioning system of the crane and thecentral locating or, respectively, positioning system. Thus, forexample, a current GPS system involves a precision of only a few metersand the relatively high number of available satellites can nonethelessnot guarantee constant availability.

Since a precision in the decimeter range is certainly desired for anembodiment of the invention, an employment of locating systems installedin a hall is realistic. The range differences between measuringinstrument and measured subject are thereby not as great as insatellite-supported systems, and the measuring precision is adequatelygood given a position measurement from a building wall to a crane or,respectively, to its load. Given a further enhancement of precision inGPS systems, however, their use is also meaningful.

Although only four embodiments of the present invention have beenillustrated and described, it will at once be apparent to those skilledin the art that variations may be made within the spirit and scope ofthe present invention. Accordingly, it is intended that the scope of thepresent invention be limited solely by the scope of the hereafterappended claims and not any wording in the foregoing description.

What is claimed:
 1. An apparatus for a three-dimensional determinationof the position of a load suspension point of a hoist from which a loadis suspended from a carrying cable, the load being movable in anx-direction, y-direction and z-direction, the apparatus comprising:atleast three microwave measuring units, each microwave measuring unitcomprising a microwave transmitter and a corresponding microwavereceiver, both the transmitter and receiver for measuring a mutualspacing between each transmitter and its respective receiver from areflective component by microwave range-finding, each microwavemeasuring unit being arranged at known positions relative to the hoist,the reflective component being arranged at a known position relative tothe load suspension point, the apparatus further comprising a pluralityof actuators for moving the load in the x-direction and in they-direction.
 2. The apparatus of claim 1 wherein the microwave measuringunits are approximately uniformly distributed around the carrying cableat a known angle with respect to the carrying cable.
 3. The apparatus ofclaim 1 wherein the reflective component is disposed adjacent to theload suspension point.
 4. The apparatus of claim 1 wherein thetransmitter and the receiver of each microwave measuring unit aredisposed adjacent to one another.
 5. The apparatus of claim 1 whereinthe transmitter and the receiver of each microwave measuring unit aredisposed adjacent to one another,wherein each microwave measuring unitis spaced laterally outward from the hoist, and wherein the reflectivecomponent is disposed adjacent to the load suspension point.
 6. Theapparatus of claim 1 wherein each of the microwave measuring unitsoperate at different frequencies.
 7. The apparatus of claim 1 furthercomprising a central locating system for determining the position of thehoist with respect to a fixed reference point.
 8. The apparatus of claim7 wherein the central locating system is a global positioning system(GPS).
 9. The apparatus of claim 1 further comprising a central locatingsystem for determining the position of the load suspension point withrespect to a fixed reference point.
 10. The apparatus of claim 9 whereinthe central locating system is a global positioning system (GPS).
 11. Anapparatus for a three-dimensional determination of a position of a loadsuspension point of a hoist from which a load suspended from a carryingcable having an adjustable length, the load being moveable in the x-, y-and z-directions, the apparatus comprising:at least two microwavemeasuring units, each microwave measuring unit comprising a microwavetransmitter and a corresponding microwave receiver, each transmitter andits corresponding receiver for measuring a mutual spacing from areflective component by microwave range-finding in combination with themeans for measuring the length of the carrying cable, the two microwavemeasuring units being disposed at known positions relative to the hoist,and the reflective component being disposed at a known position relativeto the load suspension point, the apparatus further comprising at leastone actuator for moving the load along at least one of the x-directionand the y-direction.
 12. The apparatus of claim 11 wherein the microwavemeasuring units are not arranged at opposite sides of the carryingcable, and approximate alignments of the microwave measuring unitsdefine an angle with the carrying cable.
 13. The apparatus of claim 11wherein the reflective component is disposed adjacent to the loadsuspension point.
 14. The apparatus of claim 11 wherein the transmitterand the receiver of each microwave measuring unit are disposed adjacentto one another.
 15. The apparatus of claim 11 wherein the transmitterand the receiver of each microwave measuring unit are disposed adjacentto one another,wherein each microwave measuring unit is spaced laterallyoutward from the hoist, and wherein the reflective component is disposedadjacent to the load suspension point.
 16. The apparatus of claim 11wherein each of the microwave measuring units operate at differentfrequencies.
 17. An apparatus for a determination of the position of aload suspension point of a hoist from which a load is suspended from acarrying cable, the load being movable in a z-direction as well as atleast one of an x-direction and a y-direction, the apparatuscomprising:at least one microwave measuring unit, said microwavemeasuring unit comprising a microwave transmitter and a correspondingmicrowave receiver, both the transmitter and receiver for measuring amutual spacing between each transmitter and its respective receiver froma reflective component by microwave range-finding, the at least onemicrowave measuring unit being arranged at a known position relative tothe hoist, the reflective component being arranged at a known positionrelative to the load suspension point, the apparatus further comprisingat least one actuator for moving the load along at least one of the x-and y-directions.
 18. An apparatus for a three-dimensional determinationof the position of a load suspension point of a hoist from which a loadis suspended from a carrying cable, the load being movable in anx-direction, y-direction and z-direction, the apparatus comprising:atleast three microwave measuring units, each microwave measuring unitcomprising a microwave transmitter and a corresponding microwavereceiver, both the transmitter and receiver for measuring a mutualspacing between each transmitter and its respective receiver from areflective component by microwave range-finding, each microwavemeasuring unit being arranged at known positions relative to the hoist,the reflective component being arranged at a known position relative tothe load suspension point, wherein the microwave measuring units areapproximately uniformly distributed around the carrying cable at a knownangle with respect to the carrying cable.